Portable lighting system

ABSTRACT

A system and, related method, is disclosed for enabling Chroma key compositing using a smart device, wherein an image/video of a subject situated in front of a portable monochromatic background is captured, and simultaneously layered upon a different desired background replacement that will replace only the monochromatic background captured. The portable monochromatic background structure can be an inflatable structure affixed with a plurality of lighting modules configured to ensure a uniform light distribution across the monochromatic background and separately ensure a uniform light distribution on the subject during the image/video capture. Moreover, a software application on a smart device can act as a system platform that enables for automatic light adjustment of the lighting modules on a portable monochromatic background to correct any light imperfections that impede color neutrality on the background, which would otherwise result in the inability to create broadcast quality background replacement content with a smart device using the monochromatic lighting platform disclosed herein.

CROSS REFERENCE TO RELATED APPLICATION

This application is a Divisional of U.S. Non-provisional patent application Ser. No. 15/914,641 filed Mar. 7, 2018, which in turn claims the benefit of U.S. Provisional App. No. 62/468,663 filed Mar. 8, 2017. These applications are hereby incorporated herein by reference.

FIELD OF THE INVENTION

The present invention relates generally to layering an image/video behind a captured image/video, and, more particularly, using a smart device and a mobile, physical lighting structure to create a Chroma key composite image/video with corrections for lighting imperfection.

BACKGROUND OF THE INVENTION

The term green screen has entered the mainstream language due to its widespread use by television production companies. The technical term, Chroma key compositing, or Chroma keying, involves positioning a subject in front of a monochromatic color background, capturing an image/video of the subject while simultaneously layering a desired background replacement content behind the captured image/video, and removing any visibility of the monochromatic background captured thereby displaying the background replacement content as located behind the subject. The result is an image/video where the subject deceptively appears to be in a location different from their actual location in front of the monochromatic background. Thus, a person can capture an image/video appearing to be in front of a warm sunny beach when they are actually located in a cold dark warehouse. Television production companies use Chroma key compositing for a variety of uses, including news, special effects, and video games. One of the most well-known examples is a weatherperson that appears to stand in front of a map of a given location going over the forecast, when in reality, the weatherperson is standing and looking at a blank “green screen”.

As aforementioned, Chroma key compositing consists of layering two images together with respect to color hues, wherein a specified color range is essentially made transparent, enabling a background replacement to be visible. Any color can be used as the monochromatic color, but green and blue are the most typical colors, as they provide the best distinction from most human skin colors.

Lighting is an important factor to perfecting a Chroma key composite since imperfect or non-uniform lighting on a monochromatic background may impede color neutrality, thereby potentially causing distortions in the background replacement content as it is layered. As such, traditional Chroma key compositing used by television production studios require an extensive amount of equipment, include a large monochromatic background that is surrounded by sufficient lighting, so as to ensure that a true color neutral background is achieved. Moreover, production companies may employ post-production techniques in order to correct any imperfections in such color neutrality. As such, the process in creating a high-quality Chroma key composite is time-consuming and expensive, considering the large amount of space and equipment that may be required. These requirements therefore place a burden on the average consumer attempting to execute this process, commonly known as “mobile content capture”, rendering difficulties in creating such high-quality Chroma key composites.

Current software applications exist that enable a smart device, such as a smartphone, to create a Chroma key composite image/video. However, unlike television production companies that use high quality cameras with large lights shining on the subject and background while also employing post-production techniques, a smart device's limited capability requires the image to be captured from a much closer distance to the subject. As a result, a monochromatic background is susceptible to lighting imperfections, such as shadows cast by the subject, or hotspots from unwanted external sources of light, which, result in the background replacement exhibiting such imperfections, the results of which can be fuzzy pixels in the recording or live broadcast. Thus, this provides a strain to the feasibility for an average consumer in creating a broadcast quality, high-definition Chroma key composite live and in real-time in any desired location with a smart device, considering the extensive equipment and resources that is required to create a monochromatic background that exhibits color neutrality due to uniform lighting.

It should, therefore, be appreciated that there exists a need for a system and method for creating Chroma key composite images/videos using a smart device, wherein lighting imperfections can be corrected live and in real-time to provide a color neutral background. The present invention fulfills this need and others.

SUMMARY OF THE INVENTION

Briefly, and in general terms, the invention is embodied in a portable Chroma key compositing system enabling a smart device and camera to capture an image/video of a subject located in front of a monochromatic color background, and further removing the monochromatic color background visibility to reveal a desired background content layered behind the captured image/video. The monochromatic background can be embodied in a portable structure that is affixed with targeted lighting to provide a uniform light distribution across the monochromatic background. Moreover, the smart device can be in operative communication with a background structure processor, enabling automatic lighting adjustment on the background structure to correct any lighting imperfections that impede color neutrality.

More specifically, by example and not limitation, the background structure can be embodied in an inflatable structure comprising of inflatable tubes that will be oriented in an upright position when inflated. The inflated tubes create a frame that can be enclosed with a stretchable fabric that provides a monochromatic color background featuring a back wall, with two side-walls extended thereof, and a first ceiling extending from the top of the three walls, extending partially across the open front space of the structure. The inflatable structure can also contain an overhang ceiling that extends from the first ceiling, and is used to support corrective lighting modules and block light from other sources.

In another detailed aspect of an exemplary embodiment, the inflatable structure can be affixed with lighting modules along the inner edge of the sidewalls that are focused on illuminating the background structure. Additional lighting modules can be affixed along the inner or lower edge of the first ceiling that are focused on illuminating the background structure and a subject located in front of the background. Each lighting module can consist of a plurality of light sources that are attached to a common base, such as LED ribbon lights or LED strip lights. The light sources can be configured to target illumination of the monochromatic background in smaller sections, such as by quadrant. The lighting modules can be powered by directly connecting the lighting modules to an external power source, such as a power outlet, or by connecting to an external battery that is connected to a power source, such as a Lithium battery.

In yet another detailed aspect of an exemplary embodiment, lighting modules can be affixed to the overhang ceiling, wherein said lighting modules will be focused on a subject region of whose image is being captured, so as to enable uniform lighting across the subject region. The overhang ceiling lighting modules can each consist of LED panels, distributed along the inner edge or below the overhang ceiling. The LED panels can be powered through direct connection to an external power source, or connected to a Lithium battery that is connected to an external power source, wherein the connecting power cables can run beneath the stretchable fabric. The LED panels can also be recharged while stored in a separate case.

In yet another detailed aspect of an exemplary embodiment, the background structure is affixed with a processor, acting as a controller that is in operative communication with each individual light source located on the various lighting modules attached to the background structure. Each individual light source can be assigned a specific location data point for identification by the controller. As such, the controller can adjust the illumination of each light source individually, which include dimming, brightening, and in some cases changing the color of the respective light source.

In yet another detailed aspect of an exemplary embodiment, a software application embedded on the smart device can act as a system platform for a Chroma key compositing system that can comprise the smart device, and a background structure controller, wherein said components can be in operative communication over a network. Moreover, the network may enable communication with a remote cloud server, a remote e-commerce server, and online content such as Internet web sites.

In yet another detailed aspect of an exemplary embodiment, the smart device can be a personal computing device, including a smart phone that is equipped with a camera. Moreover, the background structure controller can contain a plurality of wired and wireless data inputs, and can further receive audio data from various sources.

In yet another detailed aspect of an exemplary embodiment, the system platform can contain a database management system (DBMS) that maintains user data, login credential data, a background replacement library data, and created composites data.

In yet another detailed aspect of an exemplary embodiment, the system platform can contain a compositing module, a lighting adjustment module, an audio module, an editing module, and a cloud sync module. The compositing module provides a platform to capture an image/video of a subject that is layered simultaneously over selected background replacement content, and removes the visibility of a monochromatic color detected in the captured image/video to reveal the background replacement content as located behind the subject. The background replacement content can be an image or video played back from the DBMS, or can be a video streamed from a cloud server. The lighting adjustment module provides a platform for detecting lighting imperfections on a paired monochromatic background structure, wherein the location of the imperfections can be identified, and corrective action(s) to correct such imperfections is computed. Corrective actions include dimming or brightening the illumination imposed at the location on the monochromatic background structure used in the Chroma key process wherein lighting imperfection(s) exists. The lighting adjustment module can further relay the identified locations of the lighting imperfections and the corresponding corrective actions to a controller that will subsequently adjust the corresponding lighting sources' illumination to remove the lighting imperfections. This process enables a user to achieve perfect, live, real-time high-definition Chroma key on a smart device, wherein the background replacement content appears crisp and unnoticeable that Chroma key is even being used. The audio module provides a platform for receiving various audio inputs from the controller that can be selectively mixed and distributed with the captured image/video. The editing module enables background replacement content to be edited using features available on the smart device or cloud server, including transcoding an atypical file format to a common file format used by the system platform. The cloud sync module provides a platform to stream a truncated or entire background replacement video, that can be edited and/or looped, from a cloud server and to layer said streamed video behind a captured subject image/video. The cloud sync module further provides a platform to sync and store a background replacement video and/or image to the smart device, enabling the video and/or image to be played back for a composite image/video creation.

In yet another detailed aspect of an exemplary embodiment, the system platform enables content found over a network, such as the Internet, that was selected and stored on a remote cloud server by another software application, to be stored on the smart device by syncing the cloud server with the smart device for later background replacement. Background replacement content may be edited or looped in the remote cloud server and synced or streamed to the smart device in its edited, transcoded format.

In yet another detailed aspect of an exemplary embodiment, an e-commerce system provide a platform for background replacement content to be created, edited, purchased and sold with features that only background replacement content would require, for e.g. transcoding, re-formatting, streaming, and looping playback.

In an alternative embodiment, the background structure can be embodied in a monochromatic color pop-up screen that can be stored and opened in an umbrella fashion. The monochromatic screen can be equipped with a light cluster that extends from an intermediate section of the screen, providing a uniform light distribution across the screen. The screen height can be adjusted by being affixed to a spine that is telescoping and extendable, thereby enabling the screen to be placed on a desktop or on the floor. The screen can be folded and rotated towards the frame. The screen can be opened using a spring mechanism or electric actuation. The screen can further contain a controller in operative communication with a smart device and the screen lighting, wherein the controller can adjust the lighting to correct any lighting imperfections as detected by the smart device.

In an alternative embodiment, a smart device with a camera can be secured to a rolling frame that can be remotely positioned such that a subject can be captured and recorded by the smart device's camera, wherein the subject appears to be well-placed in a desired camera shot. The rolling frame can be equipped with a motor, that can steer and move the rolling frame, and a GPS receiver, all of which is in operative communication with a second smart device. Based on a desired location of a subject in a camera shot, the second smart device can position the rolling frame via the GPS receiver and motor such that the smart device camera secured to the rolling frame achieves the desired camera shot, also known as “blocking”. The rolling frame can further include a light stand and additional lighting modules to illuminate the subject in specific places to light the subject's chest, and to provide light above the subject, also known as the “key” light.

For purposes of summarizing the invention and the advantages achieved over the prior art, certain advantages of the invention have been described herein. Of course, it is to be understood that not necessarily all such advantages may be achieved in accordance with any particular embodiment of the invention. Thus, for example, those skilled in the art will recognize that the invention may be embodied or carried out in a manner that achieves or optimizes one advantage or group of advantages as taught herein without necessarily achieving other advantages as may be taught or suggested herein.

All of these embodiments are intended to be within the scope of the invention herein disclosed. These and other embodiments of the present invention will become readily apparent to those skilled in the art from the following detailed description of the preferred embodiments having reference to the attached figures, the invention not being limited to any particular preferred embodiment disclosed.

BRIEF DESCRIPTION OF THE DRAWINGS

Embodiments of the present invention will now be described, by way of example only, with reference to the following drawings in which:

FIG. 1A is a front angled view of a background structure in accordance with the invention depicting a monochromatic color background with a subject region.

FIG. 1B is a front side view of the background structure in FIG. 1A, depicting the exterior surface of the monochromatic background.

FIG. 1C depicts a front side view of the background structure in FIG. 1A, depicting shadows cast on the exterior surface of the monochromatic background.

FIG. 2 is an internal frame of the background structure in FIG. 1A, depicting inflated tubes standing upright.

FIG. 3A is a side view of the internal frame in FIG. 2, depicting the tubes defining the first ceiling and overhang ceiling.

FIG. 3B is a top view of the internal frame in FIG. 2, depicting the ellipsoidal top portion of the inflated tubes.

FIG. 4 is an internal frame of a background structure in accordance with the invention depicting inflated tubes standing upright.

FIG. 5A is a side view of the internal frame in FIG. 4, depicting the tubes defining the first ceiling and overhand ceiling.

FIG. 5B is a top view of the internal frame in FIG. 4, depicting the hexagonal top portion of the inflated tubes.

FIG. 5C is a back view of the internal frame in FIG. 4, depicting the tubes as connected together.

FIG. 6 is a lower side perspective view of the background structure in FIG. 1A, depicting an air-valve with a stopper affixed to a perforation in a section of the inflatable tube.

FIG. 7 is a front angled depiction of the background structure in FIG. 1A, depicting a plurality of lighting modules affixed to the structure.

FIG. 8A is a back view of a monochromatic pop-up screen in accordance with the invention, depicting the screen, a plurality of spokes and a central spine.

FIG. 8B is a side view of the monochromatic pop-up screen in FIG. 8A, depicting the screen in a closed and folded position.

FIG. 8C is a side view of the monochromatic pop-up screen in FIG. 8A, depicting a light cluster extending from an intermediate location on the screen along with an associated subject region.

FIG. 8D is a side view of the monochromatic pop-up screen in FIG. 8A, depicting the illuminating light strips along the top of the screen.

FIG. 9 is a front view of a rolling frame in accordance with the invention, depicting a wheel base, spine, device mount, light stand and light bar, and a separate lighting module.

FIG. 10 depicts a simplified block diagram of a Chroma key compositing system in accordance with the invention.

FIG. 11 depicts a simplified block diagram of a database management system (DBMS) of the system in FIG. 10.

FIG. 12 depicts a flowchart for the compositing module operation of the system in FIG. 10.

FIG. 13 depicts a flowchart for the lighting adjustment module operation of the system in FIG. 10

FIG. 14 depicts a flowchart for the streaming background module operation of the system in FIG. 10

FIG. 15 depicts a simplified block diagram of an e-commerce background replacement system in accordance with the invention.

FIG. 16A depicts a screenshot of the compositing module in FIG. 12, depicting a camera shot with a subject in front of a monochromatic background.

FIG. 16B depicts a screenshot of the compositing module in FIG. 12, depicting a camera shot with a background replacement image/video layered with a subject.

FIG. 16C depicts a screenshot of the compositing module in FIG. 12, depicting a video of a subject being captured that is layered with a background replacement image/video layered.

FIG. 17A depicts a Chroma key composite created without lighting adjustment applied, thereby resulting in lighting imperfections on the background.

FIG. 17B depicts a Chroma key composite created with lighting adjustment applied to create a well-lit background.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

With reference now to the drawings, there is shown a system and, related method, which facilitate a portable Chroma key compositing process using a portable monochromatic color background structure that is affixed with targeted lighting modules for uniform light distribution across the monochromatic background structure, and targeted lighting modules for a subject. The image/video of a subject is captured in front of the background structure and layered in front of a desired background replacement image/video in real-time, without post-production or additional equipment, wherein the visibility of the monochromatic color is removed, revealing the background replacement image/video behind the subject in sharp, high-definition. With reference to FIG. 10, a software application embedded in a smart device provides a system platform 202 to initiate and control the Chroma key compositing process, including correcting any imperfections in background color neutrality, and further providing a platform for transferring background replacement images/videos (background replacement content) to/from a remote server. As such, users can create a broadcast quality Chroma key composite image/video of a subject with a desired background replacement, without requiring the traditionally large and expensive post-production equipment, space requirements and post-production labor.

Portable Background Structure. With reference now to FIGS. 1A-B, an exemplary background structure is embodied in an inflatable structure 10, with a back wall 12, two sidewalls 14 extending thereof, a first ceiling 16 and an overhang ceiling 18 that extends from the first ceiling. The sidewalls 14 are configured to extend outwardly from the back wall 12. In an alternative embodiment, the sidewalls can be configured to extend perpendicular to the back wall. The overhang ceiling 18 is configured to extend beyond the sidewall 14 edges. Moreover, the overhang ceiling can be configured to extend perpendicular to the back wall vertical axis, i.e. horizontally, or the overhang ceiling can extend in an upward orientation, as depicted in FIG. 3A embodiment of an inflatable structure frame. The interior surfaces 20 of the back wall, sidewalls, and first ceiling display a monochromatic color, which is typically green or blue since they distinguish the most from typical human skin color. The monochromatic color displayed can however be any color as desired, provided the same monochromatic color is used. The exterior surface 22 of the inflatable structure and the entire overhang ceiling can be any color as it is not relevant within the camera shot, but provides a means to block light from other sources, as well as a structure to affix lighting modules, as described below.

Referring now to FIGS. 2-5, the inflatable structure comprises a base frame 24, 34 constructed with a plurality of connected inflatable tubes 26,28,36 configured to stand in an upright position when inflated. As described below, the tubes 26,28,36 are enclosed within a stretchable fabric (not shown) that provides the inflatable structure 10 its shape and color. The base frame may be configured in a shape resembling a vertical cylinder with an ellipsoidal top (FIGS. 2-3B), or a hexagonal configuration (FIG. 4-5B). Referring now to FIG. 2, the base frame 24 further includes four vertical tubes 28 and a connecting horizontal tube 30 thereof, that together define the back-wall, sidewalls, and first ceiling of the inflatable structure when the fabric is stretched to enclose the base frame 24. The overhang ceiling is defined by the base frame top portion that extends 32 opposite of the tubes defining the back wall. A third vertical tube 34 may be used to support the overhang ceiling, and further support a universal smart device mount (not shown) wherein a camera can be secured when capturing the image/video of the subject. The third vertical tube 34 can be removable, or rotatably joined to the base frame in a manner such that the third vertical tube 34 can be rotated upwards and placed across the longitudinal axis of the overhang ceiling. The ellipsoidal top in FIG. 2 can further be defined by a major axis 96, and minor axis 98.

The inflatable tubes 26 can be constructed with urethane, vinyl, or similar material. The exemplary embodiment depicts 4″-6″ tubes that can hold between 2 psi and 7 psi of air. Referring to FIG. 6, an air compressor (not shown) can be used to inflate the tubes 26, using a supply hose, and through a perforation 40 within a section of the tubes, wherein an air-valve 42 and stopper are used to seal the perforation. The same air-valve 42 can be used to deflate the inflatable structure, wherein the deflated structure can be stored in a carrying case or duffle bag.

With reference to FIGS. 1A-B, and as aforementioned, the base frame can be enclosed within a stretchable fabric that will securely wrap around the inflated tubes using a zip fastener, i.e. zipper affixed on the fabric. Alternatively, the fabric can be secured around the inflated tubes using hook and loop fasteners, e.g. Velcro®, or the fabric can be secured using grommets. Moreover, the positioning of the fabric over the tubes aligns the monochromatic coloring with the back-wall, sidewalls, and first ceiling. The stretchable fabric will remain attached to the frame when the inflatable structure is deflated, wherein the air-valve is accessible through an opening in the fabric.

As such, the configuration of the inflatable structure provides a portable, free standing, open-front, and semi-enclosed monochromatic color background that can be positioned behind a subject. The inflatable structure can be sized to cover a larger area behind the subject, thereby providing more flexibility in the subject's mobility, as described further below. Moreover, the inflatable structure can be “Consumerized” such that the average consumer can use the structure in conventional settings, such as a room within a house. The exemplary inflatable structure provides a 7′0″×7′0″ monochromatic background, wherein the width is measured between the edges of the two sidewalls 14. The semi-enclosed region is bounded by a 4′0″ wide back-wall 12 and 4′5″ sidewalls 14 that extend outwardly, providing a depth of 3′5″ from the sidewall edges to the back-wall. Moreover, the outermost edge of the overhang ceiling extends 4′0″ from the first ceiling.

Referring now to FIG. 7, the inflatable structure 10 can be affixed with a plurality of lighting modules that help provide a uniform light distribution across the monochromatic background 20. The vertical lighting modules 44,46 are solely oriented towards the monochromatic background 20 on the inflatable structure 10, and are located along the inner edge of the two sidewalls. The crown lighting module 48 is oriented towards the monochromatic background and an upper portion of a subject region 74. The crown lighting 48 is horizontally positioned along the inner or lower edge of the first ceiling, and is supported by the horizontal tube 30 connecting the two vertical tubes 28 for the embodiment depicted in FIG. 2, and/or the horizontal tube 94 for the embodiment depicted in FIG. 4. Each of the lighting modules 44,46,48 can consist of a plurality of light sources 50,51, such as LEDs. The light sources 50,51 for a respective lighting module 44,46,48 can be attached to a common base, e.g. LED strip light or ribbon lights. Furthermore, the light sources 50 for the vertical lighting modules 44,46 can be configured with a small beam angle, such as 15 degrees, so as to increase the light intensity in smaller focal points on the monochromatic background 20. The light sources 51 for the crown lighting module 48 can be configured with a larger beam angle, such as 45 degrees, so as to increase the illuminating focal point albeit with lower intensity. As such, and as further described below, the plurality of light sources 50,51 enable a targeted illumination of the monochromatic background 20, wherein smaller sections of the background, such as by quadrant, can be specifically illuminated. The vertical lighting modules 44,46 and crown lighting module 48 can be affixed and/or hung from the inflatable structure 10 using hook and loop fasteners, e.g. Velcro®, or grommets. Moreover, the vertical lighting modules 44,46 and the crown lighting module 48 can be powered through a direct connection to an external power source, such as wall socket. Alternatively, the vertical lighting module 44,46 and crown lighting module 48 can be powered through connection to an external battery that is in turn connected to a power source, e.g. a Lithium battery. The wiring to the external power source and external battery can be routed beneath the stretchable fabric.

With continued reference to FIG. 7, the inflatable structure can further include a plurality of overhang ceiling lighting modules 52 that are oriented towards a location in front of the monochromatic background 20 designated as the subject region 74, so as to enable uniform lighting across the subject and subject region. The overhang ceiling lighting modules 52 are affixed underneath the overhang ceiling, and can be disposed along the interior edge of the overhang ceiling. The overhang ceiling lighting modules 52 can consist of a plurality of LED lights 53. Moreover, the LED lights 53 for each ceiling lighting module 52 can be embodied in a LED panel 54 acting as a light source, wherein each LED panel 54 can be configured to hold a number of LED lights 53. For example, one embodiment of the LED panels may hold ninety (90) LED lights 53. The LED lights 53 can be powered through direct connection to an external power source, such as a wall socket, or through connection to a Lithium battery that is connected to an external power source. The power cables connecting the LED lights 53 to an external power source or a Lithium battery can be run beneath the stretchable fabric. Alternatively, the LED lights 53 can be recharged prior to being affixed to the inflatable structure, by using a Lithium battery charger that is connected to the LED lights 53 when stored, thereby negating the need for power cables to connect to the LED lights 53 while in operation on the inflatable structure 10. The overhang ceiling lighting modules 52 can be affixed to the inflatable structure using hook and loop fasteners, e.g. Velcro®, or grommets.

The vertical lighting modules 44,46, crown lighting module 48, and overhang ceiling lighting modules 52 can employ light sources 50,51,54 that include daylight-balanced lamps and that are flicker free. Other specifications for the light sources include a 96 CRI, and up to 6000 Kelvin color temperature. The overhang ceiling lighting may further enable to the light sources to range between 3000 Tungsten and 6000 Kelvin.

The inflatable structure 10 can contain a processor 92 acting as a controller that is in operative communication with each individual light source 50,51,54, wherein each individual light source 50, 51, 54 is hardwire or wirelessly connected to the processor (controller). As such, the controller is able to adjust the illumination of a specific light source 50,51,54, such as dimming, brightening, and in some cases, changing the color of the given light source. The controller identifies each light source by assigning a specific location data point that corresponds to the physical location of the light source on the inflatable structure, as determined through the hardwire connection with each individual light source 50,51,54. The controller can be embodied in a separate hardware console 92, and situated on the ground, behind the rear side of the inflatable structure. The wiring between the light sources and the controller is located beneath the stretchable fabric. The controller can further contain a wireless transceiver, wherein the controller is in operative communication with an external processor/computing device. With continuing reference to FIG. 7, an exemplary arrangement of the vertical lighting modules includes a Left Vertical Lighting 44, and a Right Vertical Lighting 46. A location data point assignment may include each of the light sources 50,51,54 being individually numbered as 1 through “n” for the corresponding lighting module 44,46,48,52, wherein “n” represents the number of light sources for the given lighting module 44,46,48,52. As such the corresponding location data point may be assigned as follows:

Location Light Source Location Data Point Right Vertical Lighting, light sources 1 to n A₁ to A_(n) Overhang Ceiling Lighting, light sources 1 to n B₁ to B_(n) Left Vertical Lighting, light sources 1 to n C₁ to C_(n) Crown Lighting, light sources 1 to n D₁ to D_(n)

As further described below, the controller on the inflatable structure will receive instructions from an external processor/computing device to adjust the illumination of specific light sources in order to correct for imperfections in color neutrality across the monochromatic background.

With reference now to FIGS. 8A-D, an alternative embodiment of a background structure is depicted using a monochromatic color pop-up screen 56. The screen 56 can be deployed in an umbrella manner from a stored position, wherein the screen is affixed to a plurality of spokes 58 that attach to a screen shaft 60. The spokes 58 can open the screen 56 through spring action or electric automation. The screen shaft 60 is rotatably affixed to a central spine 62, enabling a closed screen to be folded 64 and aligned with the central spine axis 62, thereby providing a compact storing position. The central spine can be placed upright using two support legs 66. The central spine is telescoping and extendable, thereby providing the screen 56 with an adjustable height, enabling the screen 56 to be positioned on a desktop or on the floor.

As aforementioned, the screen 56 is constructed with a monochromatic color, which is typically blue or green, but can also be black or white. The screen itself, when fully opened, is sized to provide a monochromatic background generally tailored for an upper portion 68 of a subject, such as upwards from the mid-torso of a person, e.g. a person sitting at a desk. The exemplary embodiment includes a screen size that is 4′×4′. The screen 56 is further disposed with a light cluster 70 that extends from an intermediate location on the screen 56, wherein the light cluster 70 helps provide a uniform light distribution across the monochromatic background. The light cluster 70 is positioned on the screen 56 where it will be covered by the subject, when viewed from a camera in front of the subject, to prevent interference with a captured image/video because of the illuminating light cluster 70. Moreover, illuminating strips 72 can be placed along the top of the screen 56 for additional lighting across the monochromatic background. The illuminating strips 72 are powered by a rechargeable Lithium battery located with the illuminating strips, or wired power using household 110 v AC.

The screen 56 further contains a processor (not shown) acting as a controller, that is in operative communication with each light source, namely the light cluster 70 and illuminating strips 72, through a hardwire connection. As such, the processor (controller) is able to adjust the illumination of a specific light source 70,72, such as dimming, brightening, and in some cases, changing the color of the given light source. The controller identifies each light source 70,72 by assigning a specific location data point that corresponds to the physical location of the light source on the screen, as determined through the hardwire connection with each individual light source 70,72. The controller can be situated behind or below the screen. The controller can further contain a wireless transceiver, wherein the controller is in operative communication with an external processor/computing device. As further described below, and similar to the inflatable structure 10, the controller on the screen will receive instructions from an external processor/computing device to adjust the illumination of specific light sources in order to correct for imperfections in color neutrality across the monochromatic background.

Subject Region. The subject region is a designated area wherein the subject of an image/video being captured will be situated between a camera and a background. Chroma key compositing typically requires the subject to be positioned where the camera is able to focus on the subject with a desired zoom while ensuring the background consists entirely of a monochromatic color. As such, the flexibility in a subject's location, stance, and mobility is dependent on the background structure employed. Referring now to FIGS. 1A-B and 7, the inflatable structure 10 provides a 7′×7′ monochromatic background 20 from the ground up, thereby enabling a subject's full body to be captured. A subject can also freely move about within the semi-enclosed monochromatic region 74. Moreover, multiple subjects can be captured in a camera shot while being situated within the subject region 74, thereby diversifying the types of images/videos that can be Chroma key composited. As aforementioned, the affixed crown lighting module 48 and overhang ceiling lighting modules 52 on the inflatable structure 10 will illuminate the subject, even if the camera and any other associated light sources are unable to adequately do so. By contrast, referring now to FIG. 8C, the subject region 68 is more restrictive when located in front of a pop-up monochromatic screen 56 wherein the camera is typically focused on the mid-torso upwards of a single subject. Considering the camera shot is limited by the spatial boundaries of the monochromatic screen 56, the subject region 68 is typically situated near to the monochromatic screen 56, thereby facilitating a Chroma key compositing process with minimal space requirements.

Remote Controlled Camera Positioning. With reference now to FIG. 9, an alternative embodiment to positioning a camera is depicted, wherein conventional positioning can be any means that enable the camera to adequately focus on a subject, such as hand-held positioning, placing the camera in a stand, or using the third vertical tube of the aforementioned inflatable structure. In the alternative embodiment, a smart device with a camera (not shown) can be secured to a rolling frame 76 that can be remotely controlled to “block” the shot, which as aforementioned is the positioning of the camera to obtain a desired camera shot of the subject. The rolling frame 76 comprises of a frame spine 78 rotatably attached to a frame base 80, wherein a smart device can be secured to the frame spine 76 through a universal smart device mount 82. The frame base 80 can be equipped with wheels 84, or other means for moving the rolling frame 76. The frame base 80 can also contain a motor (not shown) that can move the rolling frame 76 forward and backward, and in an exemplary embodiment, the motor can steer wheels 84 affixed to the wheel base 80. The rolling frame also contains a GPS receiver, which, along with the motor, is in operative communication with a second smart device. Using the second smart device, the rolling frame can be moved through remote control, via the motor and GPS receiver, to position the camera for optimal “blocking”.

The rolling frame 76 can further include a light stand 86 that will extend from the frame spine 78 to a location above the universal device mount 82. The light stand 86 is affixed with a light bar 88 that can illuminate the subject while an image/video is being captured. The exemplary embodiment includes a light bar 88 that is 5″-7″ wide. Moreover, a central lighting module 90 is located underneath the universal smart device mount 82 to further illuminate the subject.

The light stand 86 is rotatably attached to the frame spine 78, enabling the light stand 86 to be rotated downwards when storing the rolling frame 76. Moreover, the frame spine 78 can be folded to align with the frame base 80 to facilitate a compact storing configuration.

Chroma key Compositing Process. With reference to FIG. 10, there is shown a Chroma key compositing system that provides a platform to capture an image/video of a subject disposed in front of a monochromatic color background, and simultaneously composite the image/video with the background replacement content, while removing visibility of the monochromatic color to reveal the background replacement content as located behind the subject. The system can be further configured to address any lighting imperfections affecting color neutrality of the background. Moreover, the system can provide a platform to edit background replacement content located on a cloud server, and sync such content to the system such that background replacement content can either be played back or streamed during the Chroma key compositing process.

As aforementioned, the system, as a base configuration, comprises of hardware components that include a monochromatic background structure, a smart device, and a camera. The smart device 200 can be a smartphone or other personal computing device with wireless connectivity capability. A software application is embedded with the smart device, and acts as the system platform 202, enabling the initiation and control of the Chroma key compositing process. The software application will further use a smart device display screen to display and facilitate the Chroma key compositing process. The camera can be located on the smart device 200 itself, wherein the system platform 202 enables access to the camera functionalities. Alternatively, a remote camera 220 can be used, wherein the remote camera 220 can be located in a second smart device, or as a standalone higher quality camera, and the remote camera 220 is further in operative communication with the system platform 202. The system may also include a background structure controller 218, and further enable communication with remote servers via the network 204.

With reference to FIGS. 10-11, the system platform 202 includes a database management system (DBMS) 206 that maintains detailed data relating to user information 228, log in credentials 230, a background replacement library 232, and created composites 234. The user information data 228 and login credentials data 230 pertain to a profile for a specific user, and include information such as name, organization, username, and passwords for access to a remote server. The background replacements library data 232 contains background replacement content that have been stored onto the smart device, such as on a camera roll, and can be accessed for layering a given image/video being captured on top, i.e. creating a Chroma key composite. Background replacement content can be 1) created by a user; 2) obtained/purchased through a remote exchange server; 3) obtained from previously stored background replacement content located on the camera roll or cloud-based server; and/or 4) obtained through available background replacement content over the internet. Moreover, the cloud-based server 224 enables background replacement content of uncommon image/video formats to be transcoded to a common format that is suitable for the system platform 202. The created composites data 234 stores Chroma key composites created by the system platform 202, wherein said created composites can be distributed or uploaded to a remote sever, including the internet. The system platform 202 further includes a compositing module 208, an editing module 210, a lighting adjustment module 212, an audio module 214, and a cloud sync module 216.

Creating a Chroma Key Composite. With reference to FIG. 12, there is shown a method and exemplary operational flowchart of the compositing module 208, which provides a platform to layer an image/video of a subject being captured over a desired background replacement. The compositing module 208 will first prompt a user to select 300 a background replacement image/video from the DBMS to be layered and played back behind the image/video of the subject in real-time. A selected video may be playback in it is entirety or may be truncated, and can further be looped based on a desired length by the user. Alternatively, as further described below, a background replacement video may be streamed from a cloud server, as opposed to being played back from the DBMS, using the cloud sync module 216. Once a background replacement content has been selected, the compositing module 208 searches 302 for a monochromatic background structure to pair/connect. The pair/connection 304 can be accomplished through wireless pairing, for e.g. through a Bluetooth® connection, or connecting over a wireless network. If a pair/connection is unable to be established, the compositing module 208 will be unable 320 to determine the monochromatic color to create a Chroma key composite. The compositing module 208 can enable an “unlock code” to be purchased via the network (not shown), such that the compositing module 208 can still create a Chroma key composite, however the exact monochromatic color may not be discernible, thereby potentially rendering a Chroma key composite image/video of sub-par quality.

Once a monochromatic background has been paired 304, the system platform will obtain relevant information from the background structure such as the pre-defined monochromatic color employed, e.g. Green #255, and a pre-mapped location grid that the lighting adjustment module 212 can use to identify and pinpoint lighting location on the background structure, as further described below. The compositing module 208 will subsequently engage 306 the camera to focus on a subject located in a specified subject region that is disposed in front of the monochromatic background. The subsequent camera shot will be superimposed upon the selected background replacement content. Once the camera has the subject within the camera shot, the composite module 208 will search and detect 308 the presence of the pre-defined monochromatic color that fills up the background in the camera shot (see also FIG. 16A). As further described below, if a background structure is equipped with a controller facilitating lighting adjustment, the lighting adjustment module 212 will be accessed 318 to help ensure a uniform light distribution is imposed on the monochromatic color background. Once the composite module 208 has detected the monochromatic color presence, the compositing module 208 will essentially remove the visibility 310 of any presence of the monochromatic color in the camera shot, thereby revealing the selected background replacement content that is located behind the area where the monochromatic color was located (see also FIG. 16B). In a detailed embodiment, the compositing module 208 contains an editing component with a slider (not shown) that enables the background replacement content to be blurred so as to add the appearance of “depth” between the subject and the location that the subject appears to be in through background replacement.

The compositing module 208 subsequently enables the image/video of the subject with the background replacement content to be captured 312 (see also FIG. 16C). The created composite will be stored 314 in the DBMS for future access. In an alternative embodiment (not shown), the composite module 208 can enable a composite image/video to be captured and uploaded simultaneously to a server for viewing, i.e. live streaming of the image/video with the layered background replacement content composited.

Automated Lighting Adjustment. Referring now to FIGS. 10-11, a Chroma key compositing system can further include a controller 218 in operative communication with the system platform 202 and lighting modules affixed to a monochromatic background structure, enabling automated lighting adjustment of the said lighting modules. An example of a background structure with such communication capability is the aforementioned inflatable structure 10 (FIGS. 1A-B, 7), and pop-up screen 56 (FIGS. 8A-D), both embedded with a processor (controller) and wireless transceiver. The controller 218 can be equipped with a plurality of wired data input ports, and wireless data input ports that connect over a wireless network or wireless pairing, for e.g. Bluetooth® pairing. The controller 222 can be wirelessly connected to the smart device 200, and thereby connected to the system platform 202.

With reference now to FIG. 13, there is shown a method and an exemplary operational flowchart of the lighting adjustment module 212 for automatically correcting any lighting imperfections imposed on the monochromatic color background after it is first paired with the compositing module 208. Once the camera has detected the monochromatic color in the background structure (FIG. 12 step 308), the lighting adjustment module 212 will engage the camera to perform 402 a lighting detection analysis on the monochromatic background to determine if any lighting imperfections, or non-uniform lighting, is detected on the monochromatic background, thereby impeding color neutrality. Such lighting imperfections or non-uniform lighting can be due to shadows cast from exterior objects (see also FIG. 1C, reference character 100), hotspots created by any lighting source, and/or other factors leading to an uneven lighting distribution. The lighting detection analysis uses a pixel color-pattern recognition algorithm wherein the camera will determine if the pre-defined monochromatic color, for e.g. Green #255, is uniformly displayed in the background structure. Using Green #255 as the exemplary monochromatic color, the pattern recognition algorithm will detect 404 any shades of green that are darker or lighter than Green #255 located on the background structure. A darker shade would correspond to a shadow being present in that specific location, while a lighter shade would correspond to a hotspot being present in that location. The lighting adjustment module 212 will subsequently assign a location 406 for each shadow or hotspot found using the physical spatial boundaries of the background structure, and identify an area within the background wherein the specific shadow or hotspot is located. The pre-mapped location grid that corresponds to the paired background structure will divide the background structure into equally sized areas, such as in quadrants, and associate the location data points of the light sources on the background structure with a corresponding area. As such, the lighting adjustment module will associate a given lighting imperfection location with a specified area, and thereby determine the respective light sources on the background structure that need to be adjusted.

The lighting adjustment module will subsequently determine 406 the corrective action needed to correct the lighting imperfection. Such corrective action can include dimming or brightening the illumination on the given region on the background structure. The lighting adjustment module 212 will command 408 the controller to direct the light sources associated with the identified lighting imperfection area to execute the corrective action. As aforementioned, the background structure controller can identify each light source with a specific data location through a hardwired connection. The lighting adjustment module 212 will perform said lighting detection analysis and lighting adjustment optimization when the system platform 202 is launched or re-launched. The lighting adjustment module 212 may also be executed if requested via the system platform 202.

Additionally, the lighting adjustment module 212 can adjust lighting on an inflatable structure that is focused on a subject region. An example of this lighting is the overhang ceiling lighting modules 52 for the inflatable structure 10 depicted in FIG. 7. The lighting adjustment module 212 can adjust such subject region lighting based on different ambient conditions, such as due to different lighting during the day and at night, or in a brightly lit television studio. Such subject region lighting can be configured with presets that are controlled by the lighting adjustment module, which can include low light, medium light, or nighttime.

Referring to FIG. 17A, there is shown a Chroma key composite created without proper lights or lighting adjustment, thereby an unnatural, negative photographic effect is imposed due to the lack of lighting as well as lighting imperfections on the subject, whereas FIG. 17B depicts a composite with lighting adjustment applied to obtain a well-lit background with a properly-lit subject.

In addition to the lighting detection analysis described above, the lighting adjustment module 212 can enable fine-tuning (not shown) of the perceived color neutrality achieved through lighting adjustment, by substituting those pixels identified by the lighting adjustment module 212 as different from the pre-defined monochromatic color, with pixels of the pre-defined monochromatic color. An example of this application can be where color neutrality is unattainable in a small section of an aforementioned region, even with lighting adjustment, and thus the pixel substitution process will target the small section to ensure the entire background displays the pre-defined monochromatic color, thereby providing a sharp, high-definition viewing of the background replacement content. The pixel substitution process will detect the different shades of a monochromatic color that are present, wherein the different shades correspond to a scale defined for the given color. For example, where Green #255 represents the pre-defined monochromatic color, and the lighting adjustment module detects a small location of Green #450 in the camera shot, the lighting adjustment module will execute a command to substitute Green #450 pixels, as visible through the smart device display, with the green #255 pixels. This pixel substitution process can occur just prior to the background replacement content being made visible, and/or nearly simultaneous with the lighting detection analysis process.

In an alternative embodiment, a depth of field analysis (not shown) can be performed either in conjunction with or in place of the lighting detection analysis. The system 202 will engage the camera in a manner such that the subject in the camera shot will be in-focus while the background will be out-of-focus, thereby showing a subject that is clear while a background that may appear somewhat blurry, similar to a process accomplished by cameras equipped with F-stop settings. As such, the system will use depth of field data points as determined by the camera, to identify those pixels that are out-of-focus and replace them with a selected background replacement.

Audio Mixing. The audio module 214 provides a platform for mixing the various audio inputs received for a captured image/video, which can be in addition to audio recorded simultaneous with the captured image/video, such as from a microphone worn by the subject. As aforementioned, the controller can be wired or wirelessly connected to a plurality of audio providing devices. Such devices can include a wireless microphone located on a subject of whose image/video is being captured. Other devices include auxiliary devices such as a musical instrument, or Karaoke machine. The audio module 214 will receive audio data from the controller, and enable the one or more audio sources to be selectively mixed and distributed with the captured/capturing image/video. The audio module can also prompt for additional audio editing that include, among others, truncating the audio input(s), and specifying a truncated portion to be looped. As such the audio module 214 enables a user to determine how the various audio inputs will be integrated with the image/video being captured. The selected audio mixing and distribution will be stored and overlaid as replacement audio if desired with created composite.

Editing Background Replacement Content. The editing module 210 enables background replacement content to be edited using the smart device 200 or using features available on the cloud server. Content edited on the cloud server will be stored to the smart device through the cloud sync module 216, as described below. Using features available on the cloud server, the editing module enables background replacement files of uncommon file formats to be transcoded into common file formats suitable for the system platform 202. Additionally, using features on the cloud server, the editing module 210 enables the background replacement content to be made blurry such that when composited with an image/video of a subject, the blurriness of the background replacement content creates a depth effect to the content. This depth effect process replicates content created by a person skilled in the art of portrait photography by using an F-stop on a 35 MM camera to make a portrait of a clear, in-focus subject with a blurry background. Additionally, Chroma key composites created on a smart device can be synced to a cloud server for automated post-production video assembly, such as professionally made show introductions or introductory credits with a logo, and then synced back to the smart device for continued editing or publication.

Syncing Smart Device with Cloud Server for Background Replacement Content. With reference now to FIG. 14, there is shown a method and operational flowchart for a cloud sync module 216, which, provides a platform to sync a cloud server 224 with the smart device 200, thereby enabling background replacement videos to be streamed to the smart device, or background replacement images/videos to be downloaded to the DBMS for future playback. These background replacement files will subsequently be used for the creation of a Chroma key composite image/video. More specifically, large background replacement files may not need to be truncated due to the smaller file size of buffered streaming content, or alternatively, the cloud sync module 216 can truncate and loop a small portion to be streamed. Streaming such files avoids taking up unnecessary storage on a smart device due to downloading the files, and also avoids the smart device in using up excessive computing power to process such large files.

The cloud sync 216 module will first access a remote cloud based server 224 to identify 600 the desired background replacement, which, was previously stored on the remote cloud server 224 by a user. The editing module 210 may then be accessed 602, which as aforementioned, enables the selected background replacement file to be edited with the features available on the cloud server, including transcoding the file to a format suitable for the system platform 202. If the selected background replacement file is a video, the cloud sync module 216 will then determine 604 whether the entire video or only a portion is desired to be used, wherein if only a portion is desired, the cloud sync module 216 will enable the video to be truncated 606 to the desired length and content. The cloud sync module 216 will then determine 608 whether the background replacement video will be streamed. If the background replacement video is to be streamed, the cloud sync module 216 will sync 610 the video file with the smart device 200, enabling the video file to subsequently be streamed 612 directly as a background replacement 614 for an image/video being captured, via the compositing module 208, wherein the video can be continuously looped if desired. The streamed background replacement video file can further be stored 620 in the DBMS for future playback. In the alternative to streaming, the cloud sync module will sync 616 the cloud server to the smart device, enabling the background replacement image or background replacement video to be downloaded and stored 618 directly to the DBMS. The compositing module 208 can then playback and layer the stored background replacement image/video behind a captured image/video of a subject.

Background Replacement Capture. With reference to FIG. 10, the system platform 202 enables a user to receive background replacement content using another software application (not shown) that can capture content available on the Internet 222, and store the data on a remote cloud storage server 224. The software application can recognize copyright protected content through watermarks affixed to the content, such that the user will be unable to store said content to the cloud server 224. Once a desired image/video has been stored onto the cloud server 224, the system platform 202 can sync the smart device 200 with the obtained content for use in a Chroma key composite, and/or for storage onto the smart device 200 for future playback, as accomplished via the cloud sync module 216.

Background replacement E-commerce Platform. With reference now to FIG. 15, there is shown a system that provides users with a platform to create, edit, and exchange background replacement content, wherein the exchange can be through a monetary transaction. The system includes a database management system (DBMS) 700 that maintains detailed data relating to background replacement library, user information, and other pertinent information for enabling access and conducting transactions on an e-commerce website. The system further includes a background replacement content module 702, a background replacement editing module 704, a purchasing module 706, and a sales module 708.

The background replacement creation module 702 enables a user to create background replacement content for use on the user's smart device, and/or for others to purchase. The background replacement content can be created in any file type format. The background replacement editing module enables a user to take an existing background replacement file, either purchased or uploaded from the user's smart device, and enables the background replacement file to be edited as desired. The purchasing module enables the user to browse available background replacement content on the e-commerce server, via the background replacement library, and purchase the preferred background replacement content to create composite content. The purchased background replacement content can subsequently be stored onto a remote cloud server 224 for future syncing with the smart device 200, enabling the background replacement content to be streamed or stored onto the smart device 200 for future playback, as accomplished by the cloud sync module 216. Moreover, a user can affix the content with watermarks to ensure the content cannot be used without authorization. The sales module 708 enables a user to identify background replacement content created and/or owned by a user that is desired to be placed for sale, wherein the user can specify a price.

It should be appreciated from the foregoing that the present invention provides a system and, related method, for portably enabling Chroma key compositing where an image/video of a subject situated in front of a portable monochromatic background is captured using a smart device, and simultaneously layered over a different desired background replacement content. The system further enables the visibility of the monochromatic color to be removed, revealing the background replacement content as being located behind the subject. The portable monochromatic background structure can be an inflatable structure or pop-up screen that is affixed with a plurality of lighting modules configured to ensure a uniform light distribution across the monochromatic color background. Moreover, a software application on a smart device can act as a system platform that enables for automatic light adjustment of the lighting modules on a monochromatic background, to correct for any lighting imperfections that impede color neutrality on the background, wherein the system platform and a controller are in operative communication with the lighting modules. Moreover, the system platform enables background replacement content stored on a cloud server to be synced to a smart device, enabling the background replacement content to be streamed or stored on the smart device for future playback, and used in a Chroma key composite creation.

The present invention has been described above in terms of presently preferred embodiments so that an understanding of the present invention can be conveyed. However, there are other embodiments not specifically described herein for which the present invention is applicable. Therefore, the present invention should not to be seen as limited to the forms shown, which is to be considered illustrative rather than restrictive. 

What is claimed is:
 1. A computer implemented system for Chroma key compositing and automated lighting adjustment, comprising: a background structure, the background structure comprising: a monochromatic color area comprising a plurality of monochromatic sub-areas; a subject region disposed in front of the monochromatic color area, the subject region comprising a plurality of sub-regions; a plurality of light sources illuminating the plurality of monochromatic sub-areas and/or plurality of sub-regions; and a background structure processor in operative communication with the plurality of light sources, the background structure processor identifies each light source of the plurality of light sources with a location data point in reference to the location of the respective light source on the background structure, wherein the background structure processor is configured to dim or brighten one or more light sources of the plurality of light sources; and a computing device comprising: a processor; a computing device display; a camera; a battery; and a software application, the software application in operative communication with the background structure processor, the software application comprising: a database management system (DBMS) that maintains user data, log-in credentials data, a background replacement library data, and created composites data; a compositing module, in digital communication with the DBMS, computing device display, and background structure processor, the compositing module: retrieves a background replacement image/video from the background replacement library data; engages the camera to focus a camera shot on the subject region and monochromatic area; superimposes the camera shot over the background replacement image/video; detects the monochromatic color area in the camera shot; removes visibility of the monochromatic color area, thereby displaying the background replacement image/video located behind monochromatic color area; executes image/video capture; and stores the captured image/video in the DBMS; and a lighting adjustment module, in digital communication with the compositing module, the lighting adjustment module: detects the monochromatic color area in the camera shot; executes a light detection analysis to determine the presence of any non-uniform illumination imposed upon the monochromatic color area; identifies the one or more monochromatic sub-areas exhibiting the presence of non-uniform illumination; accesses a pre-mapped location grid of the plurality of light sources on the background structure from the background structure processor via the compositing module, and associates the one or more monochromatic sub-areas exhibiting non-uniform illumination with one or more corresponding light sources; computes a corrective action for the one or more light sources corresponding to the one or more monochromatic sub-areas exhibiting non-uniform lighting, wherein the corrective action includes dimming or brightening the respective light source; and commands the background structure processor to execute the corrective action for the one or more light sources on the background structure.
 2. The computer implemented system as defined in claim 1, wherein the lighting adjustment module is further configured to: detect any pixels in the camera shot, as displayed on the computing device display, that exhibit non-uniform lighting after the lighting adjustment has completed; identify each shade of the color displayed on the one or more pixels exhibiting non-uniform lighting, wherein each color shade is based on a corresponding color scale; access the monochromatic color data from the background structure processor via the compositing module, wherein the monochromatic color data indicates the shade of the monochromatic color; and execute pixel substitution of the one or more pixels exhibiting non-uniform lighting with pixels exhibiting the monochromatic color shade.
 3. The computer implemented system as defined in claim 1, wherein the computing device further contains a slider, such that the compositing module uses the slider to enable the background replacement image/video to be blurred, thereby creating a depth appearance between a subject in the image/video capture and the background replacement image/video.
 4. The computer implemented system as defined in claim 1, wherein the background structure processor further comprises of a plurality of wired data ports, and a plurality of wireless data ports, the background structure processor configured to receive audio data input from one or more audio transmitting devices through the plurality of wired data ports and wireless data ports.
 5. The computer implemented system as defined in claim 4, wherein the software application further contains an audio module, the audio module in digital communication with the DBMS and the background structure processor, the audio module: receives one or more audio data files from the controller; accesses image/video being captured via compositing module; assigns each audio data file of the one or more audio data files a duration to be executed with reference to the image/video, wherein one or more audio data files may be overlaid over each other; and relays each audio data file assignment to the compositing module, wherein the compositing module executes the respective one or more audio data files with the image/video being captured, such that the stored image/video will audibly include the audio data files for the prescribed duration.
 6. The computer implemented system as defined in claim 1, wherein the software application further contains a cloud sync module, the cloud sync module in digital communication with the DBMS, compositing module, and a remote cloud server, the cloud sync module: accesses the remote cloud server; identifies a video file to be used as the background replacement image/video for a Chroma key composite; determines the length of the video file to be used as the background replacement image/video; syncs the video file with the computing device; streams the video file from the remote cloud server to the computing device, wherein the compositing module superimposes the camera shot over the streaming video file, such that the video file content is visible on the computing device display when the monochromatic color area is made non-visible; and stores the streamed video file to the DBMS.
 7. The cloud sync module as defined in claim 6, wherein the cloud sync module is further configured to: access the remote cloud server; identify an image file and/or video file to be used as the background replacement image/video for a Chroma key composite; sync the image file and/or video file with the computing device; and store the image file and/or video file to the DBMS for future playback in the creation of a Chroma key composite.
 8. The computer implemented system as defined in claim 7, wherein the software application further contains an editing module, the editing module is configured to enable access to the editing features available on a cloud based server, wherein the editing features are configured to edit a background replacement image/video stored on the remote cloud server.
 9. The computer implemented system as defined in claim 8, wherein the editing module is further configured to blur the background replacement image/video.
 10. The computer implemented system as defined in claim 1, wherein the background structure is embodied in a pop-up screen structure, the pop-up screen structure comprising: a monochromatic color screen; a spine, wherein the monochromatic color screen is affixed to the spine, the spine is telescoping and extendable; a plurality of supporting legs affixed to the spine, wherein the supporting legs support the spine and the monochromatic screen in standing upright; a first plurality of light sources extending from an intermediate location on the monochromatic screen, the first plurality of light sources configured to be selectively dimmed or brightened by the background structure processor; and a second plurality of light sources affixed at the top of the monochromatic screen, the second plurality of light sources configured to be selectively dimmed or brightened by the background structure processor.
 11. The computer implemented system as defined in claim 10, wherein the monochromatic color screen further comprises: a screen shaft rotatably affixed to the spine; a plurality of spokes, wherein said plurality of spokes are joined together at the screen shaft, the plurality of spokes are extendable and collapsible; and a screen canvas, wherein the plurality of spokes are affixed to the screen canvas, such that the screen canvas is opened and stretched when the spokes are extended, and the screen canvas is closed and folded in an umbrella fashion when the spokes are collapsed.
 12. The computer implemented system as defined in claim 1, further comprising a rolling frame for remotely controlling the camera shot, the rolling frame comprising: a frame base, the frame base comprising a plurality of steerable wheels; a frame spine rotatably affixed to the frame base, the frame spine extending upright from the frame base; a universal smart device mount affixed to the frame spine, the universal smart device mount configured to secure the computing device, wherein a camera embedded on the computing device is positioned to obtain a camera shot of the background structure and subject region; a light stand affixed to the frame spine, the light stand extending upright from the fame spine and above the computing device, the light stand containing a lighting bar for illuminating the subject region; a frame spine lighting module affixed to the frame spine, the frame spine lighting module disposed below the computing device; a motor in operative communication with the plurality of wheels and a second computing device, the motor configured to steer and actuate the wheels; and a GPS receiver in operative communication with the second computing device, wherein the second computing device is configured to instruct the motor to move the rolling frame to a desired location, as determined through the GPS receiver, such that the computing device secured to the rolling frame positions the camera for a desired camera shot. 